The Practice of Genetics in Clinical Medicine Implications of Molecular Genetics for Internal Medicine The field of medical genetics has traditionally focused on chromosomal abnormalit
Trang 1Chapter 064 The Practice of Genetics
in Clinical Medicine
(Part 1)
Harrison's Internal Medicine > Chapter 64 The Practice of Genetics in
Clinical Medicine
Implications of Molecular Genetics for Internal Medicine
The field of medical genetics has traditionally focused on chromosomal abnormalities (Chap 63) and Mendelian disorders (Chap 62) However, there is genetic susceptibility to many common adult-onset diseases, including atherosclerosis, cardiac disorders, asthma, hypertension, autoimmune diseases, diabetes mellitus, macular degeneration, Alzheimer's disease, psychiatric disorders, and many forms of cancer Genetic contributions to these common disorders involve more than the ultimate expression of an illness; these genes can
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The primary care clinician is now faced with the role of recognizing and counseling patients at risk for a number of genetically influenced illnesses Among the greater than 20,000 genes in the human genome, it is estimated that each of us harbors several potentially deleterious mutations Fortunately, many of these alterations are recessive and clinically silent An even greater number, however, represent genetic variants that alter disease susceptibility, severity, or response to therapy
Genetic medicine is changing the way diseases are classified, enhancing our understanding of pathophysiology, providing practical information concerning drug metabolism and therapeutic responses, and allowing for individualized screening and health care management programs
In view of these changes, the physician must integrate personal medical history, family history, and diagnostic molecular testing into the overall care of individual patients and their families Surveys indicate that patients still turn to their primary care internist for guidance about genetic disorders, even though they may be seeing other specialists
The internist has an important role in educating patients about the indications, benefits, risks, and limitations of genetic testing in the management of
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of clinical care
Common Adult-Onset Genetic Disorders
Multifactorial Inheritance
The risk for many adult-onset disorders reflects the combined effects of genetic factors at multiple loci that may function independently or in combination with other genes or environmental factors Our understanding of the genetic basis
of these disorders is incomplete, despite the clear recognition of genetic susceptibility
In type 2 diabetes mellitus, for example, the concordance rate in monozygotic twins ranges between 50 and 90% Diabetes or impaired glucose tolerance occurs in 40% of siblings and in 30% of the offspring of an affected individual
Despite the fact that diabetes affects 5% of the population and exhibits a high degree of heritability, only a few genetic mutations (most of which are rare) that might account for the familial nature of the disease have been identified They include certain mitochondrial DNA disorders (Chap 62), mutations in a cascade
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HNF1α, IPF1, TCF7L2, glucokinase), insulin receptor mutations, and others
(Chap 338) Superimposed on this genetic background are environmental influences such as diet, exercise, pregnancy, and medications
Identifying susceptibility genes associated with multifactorial adult-onset disorders is a formidable task Nonetheless, a reasonable goal for these types of diseases is to identify genes that increase (or decrease) disease risk by a factor of two or more
For common diseases such as diabetes or heart disease, this level of risk has important implications for health In much the same way that cholesterol is currently used as a biochemical marker of cardiovascular risk, we can anticipate the development of genetic panels with similar predictive power The advent of DNA-sequencing chips represents an important technical advance that promises to make large-scale testing more feasible (Chap 62)
Whether to perform a genetic test for a particular inherited adult-onset disorder, such as hemochromatosis, multiple endocrine neoplasia (MEN) type 1, prolonged QT syndrome, or Huntington disease, is a complex decision; it depends
on the clinical features of the disorder, the desires of the patient and family, and whether the results of genetic testing will alter medical decision-making or treatment (see below)